DE10392137T5 - Method for addressing and signaling to a large number of subscriber units in a single slot - Google Patents

Abstract

Method in a system with at least one first slot, comprising the following steps:
Providing at least one field in the first slot; and
Configuring the first slot into at least a first section and a second section based on values associated with at least a portion of the at least one field associated with the first slot,
wherein the first section is addressed to a first subscriber unit and the second section is addressed to a second subscriber unit.

Description

Reference to a related registration

The present application is with the following U.S. application, Serial number 10 / 166,836, filed June 11, 2002 with the heading "Method for Assigning Inbound Transmission with Minimal Signaling Overhead "by Conrad et al. (Attorney Docket CM05093H), related to the applications Are owned by Motorola, Inc.

Territory of invention

The present invention relates generally refer to addressing and signaling procedures to a large number of subscriber units in a single slot.

background the invention

The current state of the art is used a dedicated logical control channel, e.g. a firm assigned frequency, a fixed assigned used for control Slot, etc. The current state of the art has the disadvantage that bandwidth is wasted if there is no control signaling in the transmission queue located. Even if there is control signaling in the transmission queue is another disadvantage of the current state of the Technology in that a base station or a subscriber unit of user payload packages very high priority flooded could be the one higher priority than the control and thereby the entire provided Claim channel throughput. Is there a dedicated one Control channel as in the current state of the art, this control channel is usually with temporary accumulations ("bursts") of packages with high priority not reassigned, causing unnecessary delays in user payload packets high priority to be accepted. The same applies to the control; control signaling high priority can be the entire available standing throughput of the channel, reducing the payload traffic the user is busy.

If, in addition, the available one Throughput of the channel is the throughput assigned to the channel that the user currently assigned to the channel is exceeded, the additional Throughput wasted. In the current state of the art, this can additional throughput cannot be reassigned to other users.

Accordingly, there is a need Throughput for the control and / or for the user payload slot for Slot based on priority maximize.

Short description of the drawings

It becomes a preferred one below embodiment the invention by way of example only and with reference to the enclosed figures described:

1 FIG. 3 illustrates a full duplex time division multiplex system in accordance with the present invention;

2 illustrates the total number of basic blocks that can be distributed between the two logical communication paths according to the present invention;

3A illustrates a packet data channel communication path consisting of a total of six encoded user payload blocks in accordance with the present invention;

3B illustrates a packet data channel communication path consisting of a total of six uncoded user payload blocks in accordance with the present invention;

4 illustrates a packet data channel communication path consisting of five user payload blocks and a signaling channel communication path consisting of a control block according to the present invention;

5 illustrates a packet data channel communication path consisting of four user payload blocks and a signaling channel communication path consisting of two control blocks according to the present invention;

6 illustrates a packet data channel communication path consisting of three user payload blocks and a signaling channel communication path consisting of three control blocks according to the present invention;

7 illustrates a packet data channel communication path consisting of two user payload blocks and a signaling channel communication path consisting of four control blocks according to the present invention;

8th illustrates a packet data channel communication path consisting of a user payload block and a signaling channel communication path consisting of five control blocks; and

9 illustrates a signaling channel communication path consisting of six control blocks in accordance with the present invention;

Detailed description the preferred embodiment

The present invention maximizes throughput for the controller and / or the slot by slot User payload based on priority. The present invention eliminates both the limitations of only limiting user payloads to available user payload channels and the limitation of only transferring control over associated control channels. There are no set boundaries between user payload and control channels. The present invention decides how the slot is divided based on the queued signaling and its priority.

The present invention enables a control and variable-size user payload channel within a single one Slots. This flexibility allows there is high priority signaling in as much of the throughput To avail as available is what leads to a reduction in delay. The present invention is especially for small ones Packets, such as stand-alone TCP ACKS, use a lot of the throughput available can consume.

1 illustrates physical radio frequency ("RF") outbound time-division multiplex channels (downlink) 100 and inbound time-division multiplex channels (uplink) 102 , (Time division multiplex = "TDM = time division multiplex"). The outbound channel 100 transmits information from an infrastructure to a subscriber unit or subscriber units; the inbound channel 102 transmits information from the subscriber unit or subscriber units to the infrastructure. In the present invention, the infrastructure can be any device or system that provides at least the system reference clock (e.g. the base station). Any physical channel 100 . 102 includes a stream of slots, each slot 104 is of a fixed duration. Every slot 104 includes a slot header 106 and at least one logical slot signaling channel communication path 108 ("SSCH = slot signaling channel") and / or a logical packet data channel communication path 110 ("PDCH = packet data channel"). It is important to note that the term "slot header" as used by the present invention includes control information that enables the slot to be decoded correctly; it should also be noted that the slot header can be placed anywhere within the slot (for example, at the beginning of the slot, in the middle of the slot, at the end of the slot, nested within the slot ("interleaved"), or the like). Peer-to-peer signaling and control messages are sent over the SSCH communication path 108 transfer. Data of the user level (user plane) (for example IP packets) are divided into sections and via the PDCH communication path 110 transfer.

In accordance with the present invention, each includes slot headers 106 for the outbound and inbound channels 100 . 102 at least one field. The at least one field preferably comprises an encoding scheme, logical channel multiplex information and a block format. For convenience of explanation only and for purposes of illustration, the preferred embodiment of the present invention divides this information into three fields: an encoding scheme field 112 ("COS = coding scheme"), a logical channel multiplex field 114 ("LCM = logical channel multiplexing") and a block format field 116 ("BKF = block format"). The values assigned to these fields only refer to the corresponding slot; in other words, some or all of the values associated with these fields may differ from slot to slot on a given channel. The COS field 112 determines the type of forward error correction (FEC) coding that is used for the data within the SSCH and PDCH communication paths 108 . 110 is used. The LCM field 114 determines the number of basic blocks (basic blocks are discussed below in the 2 described) by the SSCH communication path 108 be used within the slot 104 occurs. In the preferred embodiment of the present invention, everyone occupies within the SSCH communication path 108 accommodated signaling the earliest basic block or earliest basic blocks, but is not limited to this (for example, the signaling can be placed anywhere within the slot). The BKF field 116 determines the FEC modulation pairing and the order of both this pairing and that of the sections within the slot's PDCH communication path; The UCS field 116 is used in conjunction with the COS field 112 and the LCM field 114 used.

2 illustrates the total number of basic blocks 200 . 202 . 204 . 206 . 208 . 210 that exist between the two logical communication channels 108 . 110 can be distributed according to the present invention. As shown, the preferred embodiment of the present invention comprises, but is not limited to, a total of six basic blocks. Each basic block contains a constant number of symbols. The symbols of a basic block located within a slot can be physically nested across the entire slot. The present invention places no restriction on the placement of a nested symbol within the slot. For example, symbols of a first basic block, which is intended for a first subscriber unit, can be nested between symbols of basic blocks, which are intended for a second subscriber unit, within the same slot; Furthermore, since the logical SSCH and / or PDCH communication paths 108 . 110 Basic blocks include PDCH and SSCH symbols that are nested together over the entire slot. The SSCH and PDCH communication channels 108 . 110 can have any number of base blocks between zero and the total number of base blocks 220-210 in the slot 104 include. The sum of the SSCH and / or the PDCH communication paths 108 . 110 assigned basic blocks 200-210 must be the total number of basic blocks in the slot 104 (six in this example).

The SSCH communication path 108 assigned basic blocks transmit the peer-to-peer signaling and / or control messages. Each peer-to-peer signaling and / or control message is preferably preceded by its own message header (not shown), but it can also be preceded by a single message header from a group of messages. It is important to note that within a given SSCH communication path 108 there may be a large number of individual messages or more than one group of messages. Each message header comprises an address of a subscriber unit ("subscriber address"). The subscriber address in the message header allows peer-to-peer signaling and / or control messages in the SSCH communication path to be addressed in a single slot to one or more subscriber units. Each message header preferably also includes an encryption indicator. The encryption indicator shows whether a special message is encrypted; as a result, some messages within a given slot can be encrypted while others are not.

In the preferred embodiment of the present invention is the SSCH communication path 108 over the entire outbound / inbound channel 100, 102 set to a constant modulation and FEC rate; however, it is not limited to this (for example, the modulation and FEC rate could vary from slot to slot). It should be noted that the modulation rate, the FEC rate and / or the FEC type of an SSCH and a PDCH communication path 108 . 110 within the same slot 104 can distinguish.

The PDCH communication path 110 Allocated base blocks carry sectioned user payload. Each section contains a constant number of bits, some of which are assigned to a section header. In the preferred embodiment, the number of bits of each section remains constant throughout the transmission, but is not limited to this. The section header also includes a subscriber address. On the outbound communication path 100 the subscriber address allows each section to be addressed to a different subscriber unit if desired. Preferably, the section header also includes an encryption indicator. The encryption indicator shows whether the particular section is encrypted. As a result, some sections within a given slot can be encrypted while others are not.

A section can be of different types of modulations, for example 4-quadrature amplitude modulation ("QAM"), 16-QAM, 64-QAM, etc. Likewise different types of FEC are applied to a section, for example, a rate 1/2 convolutional code, a convolutional code at the rate 2/3, etc., or at all no. It is important to note that sections within a single slots with different modulation rates, FEC rates and / or can be transmitted with a different FEC type.

As mentioned above, in the preferred embodiment shows the COS field 112 the type of within a given slot 104 used FEC (for example turbo, folding, etc.); the LCM field 114 shows the number of for the SSCH communication path 108 suitable basic blocks and the BKF field 116 shows the number of sections within the PDCH communication path 110 , the type of modulation of each section, the FEC rate of each section, the location of the SSCH communication path 108 in relation to the PDCH communication path 110 as well as the arrangement of the sections within the PDCH communication path 110 on. Each of these fields is assigned a value slot by slot. Based on the above, our attention will now turn to specific examples of the present invention.

3A illustrates a PDCH communication path 110 that is made up entirely of six encoded user payload blocks 200-210 according to the present invention. In 3A for example, the value of the LCM field is 114 % 000, which indicates that in the given slot 104 no SSCH communication path 108 is available. As shown, if the value of the BKF field 116 % 010 and the value of the COS% 01 is three sections 300, 302, 304 in the PDCH communication path 110 available. A section 300 is modulated with 16-QAM and encrypted at 1/2 FEC rate, each of the other two segments 302 . 304 is modulated with 64-QAM and encrypted with the rate 2/3 FEC. In this example, the two 64-QAM modulated sections 302 . 304 the 16-QAM modulated section 300 Ahead. However, if the value of the BKF field is% 000, it is in the PDCH communication path 110 a section 306 , modulated with 4-QAM and 1/2 FEC-encrypted, available. Furthermore, the BKF field is% 100, four sections 308, 310, 312, 314 in the PDCH communication path 110 available, each modulated with 64-QAM and FEC-encrypted at the rate 2/3. As mentioned above, it is important to note that each section in PDCH communication onsweg 108 comprises a section header which opens up the possibility of addressing each section within a single slot to a different subscriber unit; for example, the first section 300 addressed to subscriber unit A, the second section 302 could be addressed to subscriber unit B and the third section 304 could be addressed to subscriber unit C.

3B illustrates an example that corresponds to that in 3A with the six uncoded user payload blocks 200-210 shown is similar. The 4 . 5 . 6 . 7 and 8th illustrate the in 3A shown similar examples with different numbers on the SSCH communication path 108 and the PDCH communication path 110 assigned basic blocks. Like for example in 4 is shown, the value of the LCM field is 114 % 001, indicating that the SSCH communication path 108 is present and a basic block 200 busy. As mentioned above, the SSCH communication path includes 108 at least one message. It is important to note that each message or group of messages includes a message header that enables each message or group of messages to be addressed to different participants in a single slot.

The same logic applies to the remaining ones in the 3A-9 illustrated examples of where in 5 the SSCH communication path 108 two basic blocks 20 . 202 occupied and the PDCH communication path 110 four basic blocks 204 . 206 . 208 . 210 busy. In 6 occupies the SSCH communication path 108 three basic blocks 200 . 202 . 204 and the PDCH communication path 110 three basic blocks 206 . 208 . 210 , In 7 occupies the SSCH communication path 108 four basic blocks 200 . 202 . 204, 206 and the PDCH communication path 110 two basic blocks 208 . 210 ; In 8th occupies the SSCH communication path 108 five basic blocks 200 . 202 . 204, 206, 208 and the PDCH communication path 110 a basic block 210 , In 9 occupies the SSCH communication path 108 six basic blocks 200 . 202 . 204, 206, 208, 210 , and the PDCH communication path 110 is not present. For these examples, it is important to note that the sum of the total number of base blocks assigned to both the SSCH and PDCH communication paths equals the total number of base blocks in the slot 104 is. Accordingly, the present invention allows the assignment of basic blocks to a communication path to vary depending on the signaling in the queue and its priority.

It should also be noted the present invention in the preferred embodiment uses a storage medium on which a command set is stored which, when loaded into a microprocessor, is the microprocessor for execution the details of the present invention described above. However, it should be apparent to those skilled in the art that the present Invention can be implemented in hardware or software.

While the invention has been described in connection with specific embodiments the expert without further advantages and modifications come to mind. The invention is therefore in its broader point of view not on the shown and described special details, realized devices and illustrative examples. Various changes, Modifications and variations will be apparent to those skilled in the art previous description be obvious. As a result it should be understood that the invention is not based on the foregoing description is limited but all the changes Modifications and variations according to the spirit and scope of attached Expectations includes.

SUMMARY THE REVELATION

In a system with at least one first slot ( 104 ) and a first header ( 106 ) is at least in the first header ( 106 ) provided a field. The first slot ( 104 ) is configured in at least a first section and a second section or in at least one signaling communication path that includes a plurality of messages based on a value associated with at least a portion of the at least one field associated with the first header connected is. The first section or the first message is addressed to a first subscriber unit and the second section or the second message is addressed to a second subscriber unit.
1

Claims (10)

Method in a system with at least one first slot that includes the following steps: Deploy at least one field in the first slot; and Configure of the first slot into at least a first section and a second Section based on values with at least one Part of the at least one field that is connected to the first slot is connected the first section being connected to a first Subscriber unit is addressed and the second section to a second Subscriber unit is addressed. The method of claim 1, wherein at least one field in the first slot is selected from a group composed of: an encoding scheme field, a logical channel multiplex field, a block format field and a combined one Field. The method of claim 1, further following Steps include: Providing at least one field in one second slot; and Configure the second slot based on values associated with at least part of the at least a field connected to the second slot are. The method of claim 3, wherein the step of Configure the second slot to split the second slots in at least one section and / or at least includes a signaling message. The method of claim 1, wherein the first section and the second section has at least one modulation rate and / or at least one forward error correction rate and / or at least one forward error correction method comprise and wherein the at least one modulation rate, the at least one forward error correction rate and / or the at least one forward error correction method of the first section of the at least one modulation rate, the at least one forward error correction rate and / or the at least one forward error correction method of the second section. Method in a system with at least a first one Slot comprising the following steps: Providing at least a first field in the first slot; and Configure the first slots in at least one signaling communication path based on a value associated with at least a portion of the at least a field that is connected to the first slot, the signaling communication path being a plurality of messages comprises and wherein at least a first message to a first subscriber unit is addressed and at least one second message to a second Subscriber unit is addressed. The method of claim 6, wherein at least one message the large number of messages is encrypted. The method of claim 6, wherein the first slot is further is configured to include a packet data communication path. The method of claim 8, wherein the first slot is one includes a fixed number of symbols, which continues the steps of Assign a first set of symbols to the signaling communication path and assigning a second set of symbols to the packet data communication path comprises, the sum of the first set of symbols and the second set of symbols equal to the fixed number of symbols is. The method of claim 6, further following Steps include: Allocate a number of with the signaling communication path symbols connected in the first slot; and To assign an uneven number of times with the signaling communication path symbols connected in the second slot.